EP1029390A1

EP1029390A1 - Communicating switch gear unit

Info

Publication number: EP1029390A1
Application number: EP98959749A
Authority: EP
Inventors: Peter Kaaden; Joachim Bury
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 1997-11-03
Filing date: 1998-10-21
Publication date: 2000-08-23
Anticipated expiration: 2018-10-21
Also published as: ATE205972T1; DK1029390T3; EP1029390B1; NO20002304L; WO1999023736A1; DE19748429A1; NO20002304D0; US6411500B1; ES2165202T3; DE59801549D1

Abstract

The aim of the invention is to provide a communicating switch and control gear unit which can be extended together with a bus system with an energy bus, by simple means and which enables shockproof connection to the energy bus. To this end, the switch- and control gear unit is provided with a modular support (2) with an integrated modular bus system (20, 21, 22). The connections (23) to an energy bus section (22) are located in a guide shaft (8).

Description

description

Switchgear unit capable of communication

The invention relates to a communication-capable switchgear unit for connection to a bus system which contains an energy bus, a data bus and at least one auxiliary power bus, the switchgear unit, which is used for the operational switching and protection of a consumer, comprising a carrier and an assembly which can be mounted thereon wherein the bus system can be inserted into the carrier and the assembly contacts the bus system after mounting on the carrier.

A generic switchgear unit is from the

EP 0 753 916 A3 is known, this being a load feeder. The power bus, the data bus and the auxiliary power bus are laid here as a busbar in the bottom part of the load feeder after it has been installed in the control cabinet. This means that it must be clear from the outset which switchgear should be provided at which point in the control cabinet. The known busbar adapter system is used to connect a motor feeder and has top-hat rails on its top, onto which a contactor and a circuit breaker can be snapped. The busbar adapter system contains a tub composed of a base part and a top part of the tub. Bracket elements are provided in the bottom part for receiving busbars. The upper part of the trough contains touch-proof openings on the front, through which contacts on an upper part of the adapter can be passed for contacting the busbars. This is done by hanging and swinging the adapter open. A communication-capable switching device unit is known from WO 96/42 188, which for switching cabinets with a data bus provides simple adaptation and contacting of switching devices in connection with electronics required for data communication. The switching device unit consists of a device carrier on which several switching devices can be adapted via a standard mounting rail, and a communication unit which is held on the device carrier and has plug contacts via which the switching devices are electrically controlled. The switchgear unit can include, for example, a contactor and a circuit breaker. If an additional switching device is required, the device carrier is extended by a device carrier extension part. Main power connections for connection to a three-phase busbar system are located on the rear wall of the device carrier of the switchgear unit. The switchgear unit is held and contacted at the same time by hanging it on the busbars. The data is transferred to the electronics in the communication module via a bus connector or by penetrating a bus line directly on the communication module.

In automation devices, as described in EP 0 236 711 A2, it is known to use subracks for adapting input / output assemblies which can be snapped onto mounting rails and which can be connected to one another via additional control lines. The subracks are individually designed here as modular subracks having an adaptation circuit. A connection block for external wiring is mechanically connected to each subrack. Terminal block and subrack can be connected to the individual subassemblies by means of a plug connection.

The adaptation circuit is designed here as a circuit board in the subrack. On the circuit board there are socket strips for connecting to plug-in connections of the Dispensing assemblies arranged. A connector strip, which is connected to the circuit board and is connected to a ribbon cable to which a socket strip is connected, is used to connect the modular subracks to one another. The electrical connection of the plug connector of the neighboring subrack can be established via this. The subracks can be connected to each other side by side by hooking laterally protruding lugs in adapted recesses in the housings of the subracks. The electrical connection is independent of this.

In the as yet unpublished German patent application

197 34 709.6 discloses a switching device system with a modular power bus. Several switching devices are operated here via the same energy feed. For this purpose, an energy bus module is assigned to each switching device, each of which has an energy bus section via which the associated switching device can be electrically connected to the energy feed. The power bus sections are connected to one another to form a continuous busbar. The energy supply can be connected to at least one of the energy bus sections.

The invention has for its object to provide a communication-capable switching and control device unit of the type mentioned above, which can be expanded with little effort including the required bus system and at the same time enables simple assembly and disassembly while maintaining contact safety when connecting to the power bus .

The object is achieved with the features of claim 1.

The design of the carrier as a modular base with an integrated modular bus system creates the possibility possibility of any expansion of the carrier system with simultaneous extension of the bus system in a single operation. This modular design allows a switchgear system to be tailored to the desired scope, using only the absolutely necessary components. As a result, significant cost savings are achieved.

The arrangement of the connections to the power bus section in a guide shaft, which is also the assembly for the

Mounting and contacting centered on the base, fulfills the functions of mechanical and electrical connection in one step. The location of the connections to the power bus section in the guide shaft achieves the required protection against accidental contact. This achieves a safe connection and disconnection of the connections to the power bus section, which is generally subjected to voltages above 100 V.

An advantageous further development of the invention exists if the assembly is coupled to the base part in such a way that a partial detachment of the assembly with simultaneous disconnection of the contact to the control bus section while maintaining the connections to the power bus section is possible. The premature disconnection of the connections to the data bus section causes the contacts of the switchgear unit to be opened, so that the operational disconnection of connected consumers from the power bus is ensured in any case. It is also hereby ensured that when the assembly is finally loosened with the

Pulling out the plug contacts to the power bus This process only takes place when the power is off.

Advantageously, the assembly is coupled by means of an articulated and / or rotating mechanism. It is also advantageous if the base part is composed of a carrier with the guide shaft and a component that can be coupled to it. This modular structure enables the application-specific modules to be coupled, ie to adapt the design to the actual requirements while minimizing costs. For the configuration of a load feeder, the module is designed as an energy bus module.

A further advantage is when the carrier is designed with a fastening element, when the carrier is actuated in one work step, the carrier can be locked onto a standard profile rail and with a further carrier in a row. This version contributes to a low assembly and disassembly effort, which has great advantages with regard to commissioning and expansion as well as testing the switching and control unit.

A particularly cost-effective version is provided if the fastening element is designed as a spring-loaded slide with a latching lug for latching with the standard profile rail and with a latching element for locking with a further carrier in a row. This is a solution with a low number of parts, which has a favorable effect with regard to the costs for production and storage. In order to pull the assembly off the carrier, it proves to be advantageous if it can be removed from the base base part by means of a pulling element on its front side. With a compact design of several switching and control unit units next to each other, simple, one-handed disassembly can be achieved.

Further options for adapting the switchgear unit to the respective system requirements are provided if the carrier is provided on it for adapting the assembly Connection side has recesses for receiving contact inserts for bus expansion, through which the modular bus system can be expanded and control inserts suitable for the contact inserts can be inserted into the module on its connection side.

The invention enables the optimization of the switch cabinet construction while at the same time incorporating the low-voltage switching devices in the automation technology. The following individual tasks can be mentioned:

- Space minimization in the control cabinet

- Reduction of assembly effort

- Simplification of assembly work - Reduction of the wiring effort for the control wiring

- Reduction of the wiring effort for the main energy

- Reduction of the testing effort

- Simplify service

For this purpose, the functions "Mechanical fastening / control wiring of the switchgear / main energy supply, distribution and outgoing / switching and protecting the consumer / commissioning and service" for groups of consumers are considered and optimized. The solution is a modular system that enables a control cabinet to be assembled simply by assembling components. The modular structure allows a switchgear system to be built with the scope just required, which results in significant cost savings.

An embodiment of the invention is explained below with reference to a drawing. Show it: 1 shows a modular load feeder with carrier and

Power bus module in the assembled state, FIG. 2 shows a view of the load feeder according to FIG. 1 in the unmounted state, FIG. 3 shows a view of the underside of a feeder assembly, FIG. 4 shows a side view of the load feeder in the assembled and contacted state, FIG. 5 shows a side view of a load feeder with a Branch module separated from the data bus in the pre-locked position,

6 shows a carrier of the load feeder according to FIGS. 1 and 2, which is latched on a standard profile rail, and FIG. 7 shows two base parts of load feeders according to FIGS.

According to FIG. 2, the modular, expandable load feeder 1 shown in FIG. 1 is essentially composed of a base part 2 and a branch assembly 3 that can be mechanically and electrically adapted thereon. The branch

Module 3 includes an intermediate carrier 4 and a contactor 5 fastened thereon and a circuit breaker 6.

The base part 2 consists essentially of an L-shaped support 7 with a guide shaft 8 on which a

Power bus module 9 is coupled. A control bus section is integrated in the carrier 7, which, for example, optionally includes a data bus section 20 and an auxiliary power bus section 21, both of which have associated connection means 10, 11 and counter-connection means 12, 13 which are accessible on both sides of the support 7 here on one side as a knife and on the other as bushes. To connect the branch module 3 to the data bus section 20 are a female header 14 on the top of the carrier, for connection to the Auxiliary power bus sections 21, the socket strips 15 and 16 are provided.

In the power bus module 9 there are the power bus sections 22, via which the main current of a consumer to be connected to the load feeder 1 is conducted. The connection to the power bus sections 22 is made via plug contacts 23 located in the guide shaft 8 and not visible here. On the front of the carrier 7 there are recesses 24 into which contact inserts 25 can be inserted if necessary. These are also with plug inserts 26 that can be retrofitted to the branch assembly 3, e.g. to control auxiliary switches of branch assembly 3, contactable.

The branch assembly 3 has a channel 27 which is form-fitting with the guide shaft 8 and is here rectangular in cross section and in which mating plug contacts 28 for contacting the plug contacts 23 are located in the guide shaft 8. The guide shaft 8 thus also serves for centering during the mechanical adaptation of the branch assembly 3 on the base lower part 2 and for the electrical connection to the energy bus section 22.

The position of the plug contacts 23 or the mating plug contacts 28 in the guide shaft 8 or channel 27 ensures the necessary protection against contact against the high operating voltages of over 100 V in the main circuit.

3 shows a bottom view of the intermediate carrier 4, which is adapted to the carrier 7 of the base lower part 2 and is L-shaped and comprises the channel 27 with the mating contacts 28. On the underside there are the knife contacts 30 and 31 used to contact the auxiliary power bus sections 21 and the contact strip 32 for connection to the data bus section 20. Via coding elements 33 on the intermediate Tray 4 and corresponding coding elements 34 on the base part (see FIG 2), the connection of certain device versions can be allowed or excluded. The control inserts 26 can be inserted in a slot 35 on the underside of the intermediate carrier 4.

4 shows a side view of the consumer feeder 1 in the adapted and contacted state, in which a detent spring 36 on the guide shaft 8 locks the feeder assembly 3 to the base part 2 against pulling. Via a latching hook 37 on the branch assembly 3, this can be released at the top. For this purpose, the branch assembly 3 is brought into a pre-latching position according to FIG. 5 after actuation of the latching hook 37. In this pre-locking position, the connection to the control or data bus section 20 is broken. The branch assembly 3 pushes the detent spring 36 back by rotating movement into the pre-locking position, whereby the locking against pulling towards the base lower part 2 is released. Only then can the branch assembly 3 be removed from the base part 2 by means of a pulling element 17 on the front side of the branch assembly

Pull off 3 as shown in FIG. The rotary movement is achieved by using the material properties and / or an articulated or rotary mechanism which, according to FIG. 2, is achieved by constructing the housing of the branch assembly 3, e.g. can be realized by a slot 38 in the intermediate carrier 4. At the same time, a spring element configuration and provision (rotary movement) of the branch assembly 3 are ensured. Instead of the rotary movement, the contact with the control bus section 20, 21 can also be released by disengaging the branch assembly 3 into the pre-latching position.

FIG. 6 shows a carrier 7 of a base lower part 2 which is locked on two standard profile rails 39. The guide shaft 8 of the carrier 7 is provided with a contour 40 for coupling various add-on elements, for example an energy bus. Module 9 according to FIG. 2 or other modules with special functions, such as brakes, thermistor protection, etc. A slide 41 is fixed to the carrier 7 with a compression spring 42 preloaded, with which the coupling to the standard profile rails 39 as well as the Locked with another, aligned base part 2. For this purpose, the slide 41 is provided on the one hand with locking lugs 43 for locking the standard profile rails 39 and on the upper side with two webs 44 which lock the locking hooks 45 on the side wall of a base part 2 in a row.

7 shows two base parts 2, which are locked on standard profile rails 39 and locked to one another, by means of which standing wiring is constructed in a modular manner. The real ones

Functional assemblies, e.g. the branch assemblies 3 are electrically contacted in connection with the mechanical adaptation on the base lower parts 2 at the same time with the entire bus system. This means a significant simplification in project planning, assembly, commissioning and the necessary tests.

Claims

claims

1. Communication-capable switching device unit for connection to a bus system which contains an energy bus, a control bus and at least one auxiliary power bus, the

Switching and control unit (1), which is used for the operational switching and protection of a consumer, comprises a carrier (7) and an assembly (3) mountable thereon, and wherein the bus system can be inserted into the carrier (7) and the assembly (3 ) contacts the bus system after mounting on the carrier (7), characterized in that the carrier is designed as a modular base part (2) with an integrated modular bus system in the form of an energy bus section (22) and a control bus section, which can optionally have a data bus section (20) and an auxiliary power bus section (21), and in that the connections (23) to the power bus section (22) are arranged in a guide shaft (8) which holds the assembly (3) centered on the base part (2) for assembly and contacting.

2. Communication-capable switching device unit according to claim 1, characterized in that the assembly (3) is coupled to the base base (2) such that a partial loosening of the assembly (3) with simultaneous disconnection of the contact to the control bus section (20) while maintaining the connections to the power bus section (22) is possible.

3. Communication-capable switching device unit according to claim 2, characterized in that the coupling of the assembly (3) is realized by an articulated and / or rotating mechanism (38).

4. Communication-capable switching device unit according to claim 1 or 2, characterized in that the base part (2) from a carrier (7) with the guide shaft

(8) and a component (9) that can be coupled to it.

5. Communication-capable switching device unit according to one of the preceding claims, characterized in that the module is an energy bus module (9).

6. Communication-capable switchgear unit according to one of the preceding claims, characterized in that the carrier (7) is designed with a fastening element (41), when it is actuated in one step, the carrier (7) is simultaneously on a standard rail (39) and with a row additional carrier (7) can be locked.

7. Communication-capable switchgear unit according to one of the preceding claims, that the fastening element as a spring-loaded slide (41) with a locking lug (43)

Locking with the standard profile rail (39) and with a locking element (45) for locking with a lined up additional support (7).

8. Communication-capable switching device unit according to one of the preceding claims, characterized in that the assembly (3) as a branch assembly (3) with a contactor (5) and a circuit breaker (6) is equipped.

9. Communication-capable switching device unit according to one of the preceding claims, characterized in that the assembly (3) is equipped with a contactor (5) and an overload relay.

10. Communication-capable switching device unit according to one of the preceding claims, characterized in that the assembly (3) by means of a pulling element (17) on its front side from the base part (2) is removable.

11. Communication-capable switching device unit according to one of the preceding claims, characterized in that the carrier (7) on its connection side provided for adapting the assembly (3) has recesses (24) for receiving contact inserts (25) through which the modular bus system can be expanded and that in the assembly (3) on its connection side for connection to the contact inserts (25) suitable plug inserts (26) can be used.